KR101400729B1 - Power generation system and power generation method using gasification for domestic waste - Google Patents

Abstract

The present invention relates to a power generating system using the gasification of domestic waste and a power generating method capable of producing synthetic gas by using the domestic waste, simplifying a preprocessing process for the production of the synthetic gas, reducing expenses for driving and installation through the reduction of pollutant loads, and significantly increasing the production of electricity. According to the present invention, provided is the power generating system using the gasification of domestic waste including a preprocessing device to process the domestic waste in a predetermined size and sort the waste; a synthetic gas producing device producing the synthetic gas by receiving the waste preprocessed in the preprocessing device and discharging remains; a post-processing device post processing the synthetic gas produced by the synthetic gas producing device; a synthetic gas engine generating device generating power by receiving the synthetic gas from the post-processing device; and a combustion gas discharging device discharging combustion gas combusted from the gas engine generating device.

Description

TECHNICAL FIELD [0001] The present invention relates to a power generation system and a power generation method using gasification of municipal wastes,

The present invention relates to a power generation system and a power generation method using gasification of municipal wastes, more specifically, it can produce syngas by using municipal wastes, simplify the pretreatment process in the production of syngas, The present invention relates to a power generation system and a power generation method using gasification of municipal wastes, which can reduce the installation cost and operation cost through the use of municipal waste and can remarkably increase the amount of electricity produced.

Generally, municipal wastes are not used due to low calorific value, and other raw materials are molded into solid fuel and used for gasification, or they are made to have a size of 50 mm or less and use a solid fuel having a low calorific value of 4,000 kcal / kg or more It is a situation that gasification is done.

In order to treat municipal waste with municipal waste as waste suitable for gasification, energy consumption is increased and construction cost and operation cost are increased. There is a problem that the application range of the wastes as the raw material for gasification is narrow and the physical size of the wastes must be adjusted to the standardized size in accordance with the standard of the woody biomass.

In gasification of municipal waste, unreacted carbon dust and tar discharged as flyashes are largely generated due to a large loss in gasification furnace and a low reaction temperature in the reaction zone of waste and oxidizer, There is a problem that the unreacted carbon content contained in the carbon black increases. In addition, there is a problem that the amount of fine carbon dust and tar generated in the syngas is increased, and thus the processing capacity of the syngas purification system must be increased.

For a system for converting waste into energy in connection with the present invention, refer to Korean Patent Publication No. 10-2013-120028 (Apr. 31, 2013) and Korean Patent Registration No. 10-0695908 (Mar. Has been proposed.

(Document 1) Korean Patent Laid-Open Publication No. 10-2013-120028 (Apr. (Document 2) Korean Patent Registration No. 10-0695908 (Mar.

In order to solve such conventional problems, the present invention solves the problem of the calorific value of municipal wastes, simplifies the pretreatment process in the production of syngas by using municipal wastes, And to provide a power generation system and a power generation method using gasification of municipal waste that can reduce operating cost and remarkably increase the electric production amount.

In particular, the present invention relates to a method for treating municipal solid waste such as carbon monoxide, hydrogen, methane, carbon dioxide, carbon dioxide, and the like by treating municipal waste with a heating amount suitable for gasification through crushing, sorting, Nitrogen is produced mainly by syngas, purified pollutants contained in syngas, and treated with clean synthetic fuel, so that it can be developed in syngas gas engine power generator. Generation system and power generation using gasification of municipal waste Method.

According to an aspect of the present invention, there is provided a pretreatment apparatus for treating municipal wastes to a predetermined size and selectively drying the municipal wastes. A syngas production device that receives the municipal waste pretreated in the pretreatment device and produces syngas at a high temperature and discharges the remainder; A post-treatment device for post-treating the synthesis gas produced by the synthesis gas production device; A syngas gas engine generator for generating syngas from the post-treatment device and generating electricity; And a combustion gas discharging device for discharging the combustion gas burned in the gas engine generator, is provided.

The pretreatment apparatus comprises: a crusher for crushing municipal waste to a predetermined size; A particle size sorter for sorting the municipal waste that has been crushed in the crusher; And a dryer for removing moisture contained in municipal wastes selected by the particle size sorter, wherein the pre-treatment apparatus further comprises a magnetic separator for sorting iron municipal wastes among the municipal wastes sorted out by the particle size sorter It is more preferable to include them.

The syngas production apparatus includes a gasification furnace for generating syngas through reaction between municipal waste and air, and discharging the residue; An air supply unit for preheating air and supplying the gas to the gasification body, and recovering waste heat of the gasification body; A syngas gas blower for sucking the syngas from the gasification furnace body; And a residue processing unit for processing the residue discharged from the gasification furnace body.

It is preferable that the gasification furnace body has a waste inlet formed at one side of the upper portion thereof, a plurality of oxidant supply nozzles for introducing air into the gasification furnace body, and a discharge port for discharging residual water at the lower portion thereof.

Wherein the gasification furnace body comprises: a cylindrical housing part having the inlet port formed at an upper portion thereof and having the plurality of supply nozzles; A hopper-like discharge portion formed at an inner lower portion of the cylindrical housing portion and having the discharge port; A partition wall extending from both ends of the inner upper portion toward the hopper-like discharge portion so that both side portions of the cylindrical housing portion form a partitioned space; A synthetic gas discharge plate having a plurality of flow holes formed at a lower end of the partition wall; And a syngas exhaust duct formed on the side wall of the cylindrical housing part to discharge the synthesis gas.

Wherein the plurality of oxidant supply nozzles are provided at an upper portion of the cylindrical housing portion; A second supply nozzle provided at equal intervals on a side of the cylindrical housing; And a third supply nozzle provided on the partition wall to supply air to a central portion of the cylindrical housing part.

The plurality of oxidant supply nozzles may further include a fourth supply nozzle provided on the discharge port side where the residue is discharged, and the partition wall may be formed as a venturi pipe.

A quantitative supply device for quantitatively supplying municipal waste to the municipal solid waste input portion of the gasification furnace; And an emission control device capable of controlling the emission amount of the residue in the exhaust port of the gasification furnace body.

Wherein the air supply unit comprises: an air blower for blowing outside air; And an air preheater connected to the supply nozzle via a connection line to preheat the air from the air blower and supply it to the gasifier body, the residue treatment unit being located below the outlet of the gasifier body Conveyor means for conveying the residue; And a residue storage tank for storing the residue transferred by the conveyor means.

The cyclone device further comprises at least one cyclone device for separating dust contained in the syngas produced in the syngas production device, wherein the cyclone device is configured such that the residue filtered by the cyclone device is discharged to the conveyor device .

The post-treatment apparatus includes a scrubbing unit for scrubbing the syngas produced in the syngas production apparatus; A dust collector for collecting dust contained in the syngas coming from the cleaning unit; A water condenser for condensing moisture contained in the syngas gas passed through the dust collector; A syngas buffer tank for storing syngas which has been dehydrated by the water condenser; And a washing water circulating water tank circulating washing water through the washing unit and storing moisture generated in the water condenser and the air preheater.

The cleaning unit may include a venturi cleaning unit configured in the form of a venturi tube and performing primary cleaning through supplied cleaning water; And a wet cleaning means for secondarily cleaning the syngas discharged through the venturi cleaning means, wherein the dust collector is composed of a wet electrostatic precipitator formed integrally with the wet cleaning means.

Wherein the combustion gas discharge device comprises: a blower blowing a combustion gas to suck combustion gas discharged from the syngas gas engine generator; And a combustion gas discharge stack for purifying and discharging the combustion gas sucked by the induction blower to the outside, wherein the exhaust gas waste heat recovering means is disposed on a discharge line through which the combustion gas is discharged from the syngas gas engine generator And the waste heat recovered by the waste heat recovering unit is supplied to the dryer and is provided as a heat source of the dryer.

According to another aspect of the present invention, there is provided a method of treating municipal solid waste, comprising: a pretreatment step of treating municipal wastes to a predetermined size and selectively drying them; A syngas production step of supplying the municipal waste treated in the pre-treatment step and producing a synthesis gas at a high temperature; A residue processing step of discharging the residue generated in the synthesis gas production step; A post-treatment step of post-treating the synthesis gas to produce synthesis gas; A syngas gas engine power generation step of supplying and generating syngas from the post-treatment step; And a combustion gas discharging step of discharging the combustion gas generated in the gas engine power generation step.

Preferably, the pretreatment step comprises crushing municipal waste to a predetermined size, sorting municipal wastes having a predetermined size from crushed municipal wastes, and drying the municipal wastes to remove moisture contained in the selected municipal wastes.

Preferably, the pretreatment step further comprises sorting the iron municipal municipal wastes out of municipal municipal wastes sorted out, and quantitatively supplying municipal wastes through the pre-treatment.

Wherein the synthesis gas production step includes supplying the oxidizing agent and the municipal solid waste into a gasification furnace to produce a syngas, wherein the oxidizing agent is supplied from the side of the gasification furnace, the side of the gasification furnace and the side of the discharge part from which the residue is discharged, Further comprising the step of transferring the residue discharged from the synthesis gas production step, storing the residue of the transferred residue, and separating the dust contained in the synthesis gas produced in the synthesis gas production step through the cyclone system .

The post-treatment step may include wet cleaning the synthesis gas produced in the synthesis gas production step, collecting dust contained in the synthesis gas, condensing the moisture contained in the synthesis gas, storing the synthetic gas from which moisture has been removed, Wherein the step of discharging the combustion gas comprises the step of sucking the combustion gas discharged from the gas engine power generation step and purifying the sucked combustion gas to discharge the combustion gas to the outside, The gas discharging step may include recovering the waste heat of the exhaust gas and providing the recovered waste heat as a heat source in the drying process in the pre-treating step.

The power generation system and the power generation method using gasification of municipal wastes according to the present invention provide the following effects.

First, the present invention can simplify the pretreatment process by a system in which a crushing, screening and drying apparatus that treats municipal waste as a gasification waste has a low calorific value of 3,500 kcal / kg or more and a waste size of 300 mm or less.

Secondly, as the size of wastes supplied to the gasification furnace and the calorific value of the gasification furnace are widened, it is possible to use a wide variety of wastes, and the gasification synthesis gas using municipal waste can be produced.

Thirdly, the present invention is characterized in that a high reaction temperature of up to 1,200 ° C is formed in the main reaction zone, which is an air supply zone of waste and oxidizing agent in the gasification furnace, and the gasification furnace structure is composed of gasification furnace inner reactor and outer reactor, The amount of fine carbon dust or tar can be reduced by using the radiant heat of the inner reactor in the outer reactor.

Fourth, the present invention can reduce the amount of tar and fine carbon dust generated in the syngas, thereby reducing the pollutant load of the syngas pollutant refining apparatus, thereby minimizing the processing scale and reducing installation and operation costs.

Fifth, the present invention can reduce the processing load of the syngas purified wastewater by reducing the amount of tar and carbon dust generated in the synthesis gas as the reaction temperature increases in the gasification furnace.

Sixth, the present invention can reduce the ignition loss of discharged bottom material to 10% or less by increasing the reaction temperature of the main reaction zone in the fixed bed gasification furnace.

Seventh, the present invention can increase the electricity production through gasification and gas engine power generation using municipal wastes.

1 is a schematic view showing a power generation system using gasification of municipal wastes according to the present invention,
2 is a view showing a gasification furnace unit constituting a power generation system using gasification of municipal waste according to the present invention, and
3 is a flow chart illustrating a method of generating electricity using municipal solid waste according to the present invention.

The power generation system and the power generation method using gasification of municipal wastes according to the present invention described below can be applied to a system and a method for producing electricity through synthesis gas generated using municipal wastes.

The power generation system and the power generation method using gasification of municipal wastes according to the present invention solve the problem of calorific value of municipal wastes and simplify the pretreatment process in the production of syngas generated in the treatment of municipal wastes, It is possible to reduce the installation cost and the operation cost by reducing the load and to remarkably increase the electric production amount.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted for the sake of clarity and conciseness.

First, a power generation system using gasification of municipal wastes according to the present invention will be described with reference to FIG. FIG. 1 is a schematic view showing a power generation system using gasification of municipal waste according to the present invention, FIG. 2 is a diagram showing a gasification furnace unit constituting a power generation system using municipal solid waste according to the present invention to be.

As shown in FIGS. 1 and 2, the power generation system using municipal solid waste according to the present invention includes a pretreatment apparatus 100 for treating and sorting municipal waste, which is greatly input, into a standard for gasification; A syngas production device that receives the municipal waste pretreated in the pretreatment device 100 to produce a syngas, and discharges a solid residue (a bottom material); A post-treatment device for post-treating the syngas produced by the syngas production device to produce pure syngas; A syngas gas engine generator 400 for generating syngas from the post-treatment apparatus and generating electricity; And a combustion gas discharge device 500 for discharging the combustion gas burned in the gas engine power generation apparatus 400.

The pretreatment apparatus (100) comprises a crusher (110) for crushing municipal wastes into a predetermined size; A particle size separator (120) for selecting municipal wastes having a predetermined particle size from the municipal wastes crushed by the crusher (100); And a dryer 130 for removing moisture contained in the municipal waste selected by the particle size separator 120.

The pretreatment apparatus 100 further includes a magnetic separator 140 for sorting iron municipal solid waste (municipal municipal waste) among the municipal wastes sorted out by the particle size sorter 120.

In order to treat municipal waste as waste for gasification, the pretreatment apparatus 100 is set to produce a calorific value of less than 3,500 kcal / kg and less than 300 mm. In order to maintain the quality of the waste for gasification, Removing the fireproof door and reducing the water content.

As will be described later, the dry heat source supplied to the dryer 130 may recover the waste heat of the exhaust gas discharged from the syngas gas engine generator 400.

The gasification municipal waste finally dried in the dryer 130 of the preprocessing apparatus 100 is supplied to the synthesis gas production apparatus through the supply line 150.

The syngas production apparatus includes a gasification furnace body 210 for generating a syngas by reacting the incoming waste with air, which is an oxidant, and discharging solid residues; An air supply unit for preheating air as an oxidizer and supplying the gas to the gasification body 210 and recovering waste heat of the gasification body 210; A synthetic gas blower 220 for sucking the syngas produced in the gasification furnace body 210 to send it; And residue processing units 231 and 232 for processing the solid residue (bottom) discharged from the gasification furnace body 210.

In addition, the gasification furnace body 210 is provided with a waste inlet 211 at one side of the upper part thereof, a plurality of oxidant supply nozzles 212a, 212b, 212c and 212d for supplying air as an oxidant, And an outlet 213 for discharging the residue (floor material) is formed.

The gasification furnace body 210 includes, as one embodiment thereof, a cylindrical housing part 214, as shown in detail in FIG. 2; A hopper-type discharge unit 215 formed at an inner lower portion of the cylindrical housing unit 214; A partition wall 216 extending in the form of a venturi pipe from the inner upper end of the cylindrical housing part 214 to the hopper-shaped discharge part 215 side so that both side parts of the cylindrical housing part 214 form a partitioned space; A synthetic gas discharge plate 217 having a plurality of flow holes formed at a lower end of the partition wall 216; And a syngas exhaust duct 218 formed on the side wall of the cylindrical housing part 214 to discharge syngas.

In the gasification, the body 210 has a partitioning space 216 at the center of the cylindrical housing part 214 and at the outside of the central part thereof. The compartment space at the central part is divided into the chamber A by the downflow gasification, And the compartment spaces on both sides form the chamber B by the upward flow gasification.

The plurality of oxidant supply nozzles include a first supply nozzle 212a for supplying air as an oxidant to the upper portion of the cylindrical housing portion 214; A second supply nozzle 212b provided at a side of the cylindrical housing 214 to supply air as an oxidant to the side (i.e., the upward flow gasification chamber B) thereof; And a third supply nozzle 212c provided in the partitioning wall 216 to supply air as an oxidant to the central portion of the cylindrical housing portion 214 (i.e., the downflow gasification chamber A).

The plurality of oxidant supply nozzles further include a fourth supply nozzle 212d on the side of the discharge port 213 through which the solid residue is discharged and the fourth supply nozzle 212d is provided to move toward the discharge port 213 side The flammable components contained in the solid residues (bottoms or solids) are reacted with air, which is the oxidizing agent, to maximize the treatment efficiency. Therefore, it is possible to reduce the amount of combustible components contained in the discharged solid residue (bottom material) and increase the ratio of the combustible fraction converted into the synthesis gas, thereby increasing the amount of energy used as the fuel for power generation.

The first supply nozzle 212a is configured to provide air from the top of the cylindrical housing 214 to enable maintenance of the operating temperature at the top of the cylindrical housing portion 214. [

A plurality of the third supply nozzles 212c are arranged at equal intervals in the circumferential direction so as to be uniformly reacted with the waste to be charged, and the reactivity of the waste and the oxidizer is increased through the oxidant supply rate control, So as to increase the conversion rate of the waste, thereby reducing the amount of tar and fine carbon dust, which are highly pollutants.

The gasification furnace body 210 is provided at the discharge port 213 to maintain the residence time of the solid residue in the cylindrical housing part 214 for a predetermined time and to control the discharge amount control (Not shown). Such an emission control device can control the ignition loss of the solid residue to be less than 10% so as to convert the combustible material into gasification in the main gasification reaction zone.

The inlet of the syngas production apparatus to which the supply line 150 is connected is provided with a fixed amount supply unit 240 for supplying municipal waste of a predetermined size (that is, 300 mm or less) quantitatively as described above.

Subsequently, the air supply unit includes an air blower 250 for blowing outside air; And an air preheater 260 connected to each supply nozzle via one or more connection lines 261 to preheat the air from the air blower 250 and supply it to the gasification body 210.

The air preheater 260 is disposed at the downstream end of the gasification furnace 210 to preheat the air, which is an oxidizing agent, into the gasification furnace 210. As a result, the preheated air is preheated by the air preheater 260 first, and the preheated air is further preheated by using the heat dissipation loss (chamber B region) of the body 210 by the second gasification so as to utilize the waste heat more efficiently do. Also, as the preheated air is passed through the chamber B region by gasification, the temperature of the gas introduced into the body 210 through the oxidizing agent supply nozzle can be maintained or raised, thereby maximizing the gasification reactivity.

The residue processing units 231 and 232 include conveyor means 231 positioned below the discharge port 213 of the gasification furnace 210 for transferring the discharged exhaust gas; And a remainder reservoir (232) for the remainder being conveyed by the conveyor means (231).

In the meantime, the present invention further includes at least one cyclone device 270 for separating the dust contained in the syngas provided between the gasification furnace body 210 and the air preheater 260 of the syngas production apparatus.

The cyclone device 270 is configured such that the separated syngas is supplied to the air preheater 260, and the filtered residue is discharged to the conveyor means 231 described above.

Next, a post-treatment apparatus produced in the synthesis gas production apparatus will be described. The post-treatment apparatus is provided on the path through which the produced syngas is supplied to the gas engine generator.

The post-treatment apparatus includes a cleaning unit for cleaning the syngas coming from the air preheater 260; A dust collector (310) for collecting dust contained in the syngas coming from the cleaning unit; A water condenser (320) for condensing moisture contained in the syngas discharged from the dust collector (310); A syngas buffer tank 330 for temporarily storing the dehydrated synthesis gas by the moisture condenser 320; And a washing water circulating water tank 340 circulating the washing water through the washing unit and collecting moisture stored in the water condenser 320 and the air preheater 260. [

The cleaning unit includes a venturi cleaning unit 351 that is formed in the form of a venturi tube and primarily cleans the syngas flowing in the interior thereof through the washing water supplied from the washing water circulating water tank 340; And a wet cleaning means 352 for secondarily cleaning the syngas discharged through the venturi cleaning means 351.

Preferably, the dust collector 310 is formed of a wet electrostatic precipitator, and is integrally formed with the wet cleaning means 352.

The syngas gas engine generator 400 may employ known ones, and a detailed description thereof will be omitted for the sake of simplicity of description of the present invention. Here, the present invention includes a bypass line 410 connecting the inlet side and the outlet side of the syngas gas engine generator 400; And syngas combustion means 420 provided in the bypass line 410.

Next, the combustion gas discharging device includes a blowing fan 510 for sucking the combustion gas discharged from the syngas gas engine generator 400; And a combustion gas discharge stack 520 for purifying the combustion gas sucked by the induction blower 510 and discharging the combustion gas to the outside.

Here, the gas engine exhaust gas waste heat recovery means 620 is further provided on the exhaust line 610 through which the combustion gas is discharged from the syngas gas engine power generation apparatus 400 to the combustion gas discharge apparatus discharge apparatus, The waste heat recovered in the means 620 is supplied to the dryer 130 and equipped with a waste heat connection line 630 so that it can be used as a heat source.

Next, a method of generating electricity using municipal solid waste according to the present invention will be described with reference to FIG. 3 is a flow chart illustrating a method of generating electricity using municipal solid waste according to the present invention.

As shown in FIG. 3, the method for generating gas using municipal solid waste according to the present invention includes a pre-treatment step (S100) for treating and sorting municipal waste into a standard for gasification; A syngas production step (S200) of producing a synthesis gas by receiving the municipal waste pretreated in the pre-treatment step (S100); An exhaust residue processing step S300 for processing the solid residue (bottom material) generated and discharged in the syngas production step S200; A post-treatment step (S400) for post-treating the synthesis gas produced in the synthesis gas production step; A syngas gas engine power generation step (S500) of supplying a syngas from the post-treatment step and generating electricity; And a combustion gas discharge step (S600) for discharging the combustion gas burned in the gas engine power generation step (S500).

The pretreatment step (S100) includes crushing the municipal wastes into a predetermined size, sorting the municipal wastes having a predetermined size from the crushed municipal wastes, and drying the municipal wastes to remove moisture contained in the selected municipal wastes.

In addition, the pre-processing step (S100) further includes the step of selecting the magnetic iron oxide municipal solid waste (municipal municipal solid waste) among the municipal solid wastes.

In addition, the pre-processing step (S100) further includes the step of supplying the municipal waste to be supplied through the pretreatment quantitatively.

In order to treat municipal wastes as wastes for gasification, the pre-treatment step (S100) is processed to produce low calorific value of 3,500 kcal / kg or more and 300 mm or less. In order to maintain the quality of the waste for gasification, Removing the fireproof door and reducing the water content.

In the synthesis gas production step (S200), synthesis gas is produced through the reaction of municipal waste, which is an oxidant, input through a certain type of gasification furnace.

Specifically, in the synthesis gas production step (S200), the air as the oxidizer is preheated and supplied to the gasification furnace, the syngas is generated through the reaction between the incoming waste and the air as the oxidizer, the waste heat of the gasification furnace is recovered, Wherein the supply of the air, which is the oxidizer, is supplied from the side of the upper part and the side of the gasification furnace and the side of the discharge part from which the residue is discharged.

In addition, it is preferable that the gasification furnace is configured such that the flow of the synthesis gas produced in the synthesis gas production step (S200) flows at least once in the upward flow and the down flow.

The discharge residue treatment step (S300) includes transferring the residue discharged in the syngas production step and storing the transferred residue as a residue.

The present invention further comprises separating the dust contained in the syngas produced in the synthesis gas production step through a cyclone system, wherein the residue (solid matter) separated by the cyclone system is separated into the residue As shown in FIG.

Next, in the post-treatment step (S400), the synthesis gas produced in the synthesis gas production step, which is selectively subjected to the cyclone separation, is wet-cleaned, the dust contained in the synthesis gas is collected, Condensed water, and stores the synthetic gas from which moisture has been removed to provide the gas engine power generation stage.

The syngas gas engine power generation step (S500) may be performed using a known gas engine.

The combustion gas discharge step (S600) includes sucking the combustion gas discharged from the gas engine power generation step, purifying the inhaled combustion gas, and discharging the combustion gas to the outside.

Here, the flue gas discharge step includes recovering waste heat of the exhaust gas and providing the recovered waste heat as a heat source in the drying process in the pre-treatment step.

In the high temperature gasification according to the present invention, the operation temperature is in the range of 850 to 1,200 ° C in the main reaction zone, which is the air supply zone which is the waste and oxidizing agent in the gasification furnace, and the operation temperature is 1,200 ° C, The reaction temperature of the oxidizing agent and the waste is 1,200 ° C, which means the highest temperature of the gasification furnace.

High temperature gasification increases the conversion rate of combustible components contained in waste into syngas and improves the amount of tar and micro carbon dust generated as a result of unreacted substances and is included in incombustibles discharged as flooring materials The content of the combustible component can be reduced. Therefore, it is possible to increase the amount of power generated by the syngas, which is fuel of the gas engine, by increasing the efficiency of the waste to increase the total syngas production energy. By reducing the amount of tar and fine carbon dust generation, the pollutant loading of the syngas refining facility can be reduced to reduce the associated operating costs and the maintenance of the syngas refining system is more stable.

The power generation system and the power generation method using gasification of municipal wastes according to the present invention can be applied to a system and a method for producing electricity through synthesis gas generated using municipal wastes.

The power generation system and the power generation method using gasification of municipal wastes according to the present invention can solve the problem of the heating value of municipal wastes and simplify the pretreatment process in the production of syngas generated in the treatment of municipal wastes It is possible to reduce the installation cost and operation cost through reduction of the pollutant load, and it is advantageous to remarkably increase the electric production amount.

As described above, the power generation system and the power generation method using gasification of municipal wastes according to the present invention have been described with reference to the drawings. However, the present invention is not limited to the embodiments and drawings described above, It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention.

100: preprocessing device 110: crusher
120: particle size selector 130: dryer
140: magnetic separator 210: gasification body
212a, 212b, 212c, 213d: oxidant supply nozzle
213: outlet 214: cylindrical housing part
215: hopper-type discharge part 216:
217: Synthetic gas discharge plate 218: Synthetic gas discharge duct
220: Syngas induction blower 231: Conveyor means
232: Residual reservoir 240: Quantitative feeder
260; Air preheater 270: Cyclone device
310: dust collector 320: water condenser
330: Synthetic gas butter tank 340: Rinse water circulation water tank
400: Syngas gas engine generator 410: Bypass line
420: Syngas combustion means 500: Combustion gas discharge device
510: combustion gas induction blower 520: combustion gas exhaust stack
610: discharge line 620: waste heat recovery means
630: waste heat connection line
S100: preprocessing step
S200: Synthetic gas production stage
S300: Exhaust residue treatment step
S400: Post-processing step
S500: Synthetic gas gas engine development stage
S600: Flue gas discharge step

Claims (19)

A pretreatment device for treating municipal wastes to a predetermined size and selectively drying them;
A syngas production device that receives the municipal waste pretreated in the pretreatment device and produces syngas at a high temperature and discharges the remainder;
A post-treatment device for post-treating the synthesis gas produced by the synthesis gas production device;
A syngas gas engine generator for generating syngas from the post-treatment device and generating electricity; And
And a combustion gas discharging device for discharging the combustion gas burned in the gas engine generator,
The syngas production apparatus
A gasification body that produces syngas through the reaction of municipal waste with air and discharges the residue;
An air supply unit for preheating air and supplying the gas to the gasification body, and recovering waste heat of the gasification body;
A syngas gas blower for sucking the syngas from the gasification furnace body; And
And a residue processing unit for processing the residue discharged from the gasification body,
The gasification furnace body
A plurality of oxidant supply nozzles for supplying air are provided, and a discharge port for discharging the remaining water is formed in the lower portion
Power generation system using gasification of municipal waste.
The method according to claim 1,
The pre-
A crusher for crushing municipal waste into a predetermined size;
A particle size sorter for sorting the municipal waste that has been crushed in the crusher; And
And a dryer for removing moisture contained in the municipal waste selected by the particle size separator
Power generation system using gasification of municipal waste.
The method of claim 2,
The pre-
Further comprising a magnetic separator for sorting municipal solid waste among the municipal wastes sorted out by the particle size sorter
Power generation system using gasification of municipal waste.
delete delete The method according to claim 1,
The gasification furnace body
A cylindrical housing part having the inlet port formed at an upper portion thereof and having the plurality of supply nozzles;
A hopper-like discharge portion formed at an inner lower portion of the cylindrical housing portion and having the discharge port;
A partition wall extending from both ends of the inner upper portion toward the hopper-like discharge portion so that both side portions of the cylindrical housing portion form a partitioned space;
A synthetic gas discharge plate having a plurality of flow holes formed at a lower end of the partition wall; And
And a syngas exhaust duct formed in the side wall of the cylindrical housing part to discharge the synthesis gas
Power generation system using gasification of municipal waste.
The method of claim 6,
The plurality of oxidant supply nozzles
A first supply nozzle provided at an upper portion of the cylindrical housing part;
A second supply nozzle provided at equal intervals on a side of the cylindrical housing; And
And a third supply nozzle provided on the partition wall for supplying air to a central portion of the cylindrical housing portion
Power generation system using gasification of municipal waste.
The method of claim 7,
The plurality of oxidant supply nozzles
And a fourth supply nozzle provided at the discharge port side from which the residue is discharged,
The partition wall is formed in a venturi tube shape
Power generation system using gasification of municipal waste. The method of claim 6,
A quantitative supply device for quantitatively supplying municipal waste to the municipal solid waste input portion of the gasification furnace; And
And an emission control device capable of controlling the emission amount of the residue in the exhaust port of the gasification furnace body
Power generation system using gasification of municipal waste.
The method according to claim 1,
Wherein the air supply unit comprises: an air blower for blowing outside air; And an air preheater connected to the supply nozzle through a connection line to preheat the air from the air blower and supply it to the gasifier body,
Said residue processing unit comprising: conveyor means positioned below an outlet of said gasifier body for conveying a residue; And a residue reservoir for transferring the residue transferred by the conveyor means
Power generation system using gasification of municipal waste.
The method of claim 10,
Further comprising at least one cyclone device for separating dust contained in the syngas produced in said syngas production device,
Wherein the cyclone device is configured such that a residue filtered at the cyclone device is discharged to the conveyor means
Power generation system using gasification of municipal waste.
The method of claim 10,
The post-
A scrubbing unit for scrubbing the syngas produced in the syngas production apparatus;
A dust collector for collecting dust contained in the syngas coming from the cleaning unit;
A water condenser for condensing moisture contained in the syngas gas passed through the dust collector;
A syngas buffer tank for storing syngas which has been dehydrated by the water condenser; And
And a washing water circulating water tank circulating washing water through the washing unit and storing moisture generated in the water condenser and the air preheater
Power generation system using gasification of municipal waste.
The method of claim 12,
The cleaning unit may include a venturi cleaning unit configured in the form of a venturi tube and performing primary cleaning through supplied cleaning water; And a wet cleaning means for secondarily cleaning the syngas discharged through the venturi cleaning means,
Wherein the dust collector comprises a wet electrostatic precipitator formed integrally with the wet cleaning means
Power generation system using gasification of municipal waste.
The method of claim 2,
Wherein the combustion gas discharge device comprises: a blower blowing a combustion gas to suck combustion gas discharged from the syngas gas engine generator; And a combustion gas discharge stack for purifying and discharging the combustion gas sucked by the induction blower to the outside,
The exhaust gas waste heat recovering means is further provided on a discharge line through which the combustion gas is discharged from the syngas gas engine generator,
The waste heat recovered by the waste heat recovering means is supplied to the dryer and is provided as a heat source of the dryer,
Power generation system using gasification of municipal waste.
A pretreatment step of treating municipal wastes to a predetermined size and selectively drying them;
A syngas production step of supplying the municipal waste treated in the pre-treatment step and producing a synthesis gas at a high temperature;
A residue processing step of discharging the residue generated in the synthesis gas production step;
A post-treatment step of post-treating the synthesis gas to produce synthesis gas;
A syngas gas engine power generation step of supplying and generating syngas from the post-treatment step; And
And a combustion gas discharging step of discharging the combustion gas burned in the gas engine power generation step,
The pretreatment step may include crushing the municipal wastes into a predetermined size, sorting the municipal wastes having a predetermined size from the crushed municipal wastes, and drying the municipal wastes to remove moisture contained in the selected municipal wastes,
The post-treatment step may include wet cleaning the synthesis gas produced in the synthesis gas production step, collecting dust contained in the synthesis gas, condensing the moisture contained in the synthesis gas, storing the synthetic gas from which moisture has been removed, To a gas engine power stage,
Wherein the combustion gas discharge step includes sucking the combustion gas discharged from the gas engine power generation step, purifying the sucked combustion gas, and discharging the combustion gas to the outside,
The burning gas discharge step may include recovering waste heat of the discharged combustion gas and providing the recovered waste heat as a heat source in the drying process in the pre-
Development method using gasification of municipal waste.
delete 16. The method of claim 15,
The pre-
Further comprising sorting the iron municipal municipal wastes among the municipal wastes sorted out and allowing the municipal wastes to be supplied through the pre-treatment to be quantitatively supplied
Development method using gasification of municipal waste.
16. The method of claim 15,
Wherein the synthesis gas is produced by supplying oxidizing agent and municipal waste to a gasification furnace to produce a synthesis gas, wherein the oxidizing agent is supplied from an upper portion and a side portion of the gasification furnace and a discharge portion from which the residue is discharged,
The step of treating the discharged residues comprises the steps of transferring the residues discharged in the syngas production step, storing the transferred residues as residues,
And separating dust contained in the syngas produced in the synthesis gas production step through a cyclone system
Development method using gasification of municipal waste.

delete

Images